A power system includes an engine; an exhaust gas recirculation (EGR) system supplying a first portion of the engine exhaust gas from the exhaust manifold to the intake manifold; a turbine generator in communication with the exhaust manifold and configured to be driven by a second portion of the engine exhaust gas from the exhaust manifold to generate electrical power; a power network including at least one battery to store the electrical power generated by the turbine generator; and an electric compressor in fluid communication with the intake manifold and configured to be powered by the electrical power from the at least one battery of the power network and to compress at least a portion of the intake air for the engine.

Provided is a utility vehicle including a seat, an engine disposed rearward of the seat, and a supercharger disposed between the seat and the engine.

The disclosed invention includes systems and methods to improve the efficiency of combustion engines through the use of air separator technology. In some embodiments, a system for improving engine efficiency includes a compressor configured to take in a flow of ambient air and output a supply of pressurized air to one or more air separators. The air separator(s) produce a supply of oxygen enriched air, which is conveyed to the combustion chamber(s) of an engine. The air separators also produce a supply of exhaust air, which may be used to power system components, or other components. Other embodiments include methods of improving engine efficiency by pressurizing ambient air, supplying the pressurized air to an air separator to produce oxygen-enriched air, and supplying the enriched air to an engine's combustion chamber(s). Some embodiments use a supply of exhaust air from the air separator to power system components and other components.

Fluid pumping system for a vehicle with an internal combustion engine, the fluid pumping system comprising: a housing; an electric motor; a planetary gear with a first member that can be driven by the internal combustion engine, a second member driven by the electric motor, and a third member; and a pump driven by the third element of the planetary gear set, the housing being closed by a pump flange and a pulley with pulley cover, wherein at least the pulley and/or a ring gear disposed in the pulley is made of plastic.

Fluid pumping system for a vehicle with an internal combustion engine, the fluid pumping system comprising: a housing; an electric motor; a planetary gear with a first member that can be driven by the internal combustion engine, a second member driven by the electric motor, and a third member; and a pump driven by the third element of the planetary gear set, the housing being closed by a pump flange and a pulley with pulley cover, wherein at least the pulley and/or a ring gear disposed in the pulley is made of plastic.

A turbocharger (1) includes a turbine wheel (3) driven by exhaust gas, first and second compressor wheels (4, 5) coaxially coupled to the turbine wheel (3) via a shaft member (6), a compressor housing (8) accommodating the first and second compressor wheels (4, 5) and having defined therein a communication passage (17) through which air compressed by the first compressor wheel (4) flows to the second compressor wheel (5), and an electric motor (11) arranged in the communication passage (17) and using the shaft member (6) as a rotation shaft thereof.

A turbocharger (1) includes a turbine wheel (3) driven by exhaust gas, first and second compressor wheels (4, 5) coaxially coupled to the turbine wheel (3) via a shaft member (6), a compressor housing (8) accommodating the first and second compressor wheels (4, 5) and having defined therein a communication passage (17) through which air compressed by the first compressor wheel (4) flows to the second compressor wheel (5), and an electric motor (11) arranged in the communication passage (17) and using the shaft member (6) as a rotation shaft thereof.

A radial turbine for a charging device with a turbine casing, a turbine wheel, a VTG guide grid, and a plurality of spacing elements. The spacing elements are arranged on the vane bearing ring and define an axial distance of the vane bearing ring from the turbine casing or from a counter-element arranged in the turbine casing. At least one spacing element is arranged adjacent to a guide vane and is configured such that a minimum distance between the at least one spacing element and the associated adjacent guide vane is achieved in a specific operating position of the guide vane in which the minimum distance is formed by a difference between an axial distance and an inflow distance.

A radial turbine for a charging device with a turbine casing, a turbine wheel, a VTG guide grid, and a plurality of spacing elements. The spacing elements are arranged on the vane bearing ring and define an axial distance of the vane bearing ring from the turbine casing or from a counter-element arranged in the turbine casing. At least one spacing element is arranged adjacent to a guide vane and is configured such that a minimum distance between the at least one spacing element and the associated adjacent guide vane is achieved in a specific operating position of the guide vane in which the minimum distance is formed by a difference between an axial distance and an inflow distance.

An intake system of engine comprises an intake pipe (8), an air intake manifold (6), and an auxiliary intake assembly (4) disposed on the intake pipe (8) and located before the air intake manifold (6) of an engine. The auxiliary intake assembly (4) comprises an auxiliary air inlet passage, an auxiliary air outlet passage (21), and a central passage (39). Air enters through the auxiliary air inlet passage, comes out from the auxiliary air outlet passage (21) and enters the central passage (39), so as to be mixed with air from the intake pipe (8). The present invention further relates to an engine intake system, comprising an electronic booster (4″) located upstream of the air intake manifold (6) of an engine. An air flow enters from an air inlet (4241″), flows out from an air outlet (4242″), is mixed with air that flows through the intake pipe (8), and then is inhaled into a cylinder of the engine. The present invention further relates to a engines comprising the above intake systems. These intake systems and engines can effectively reduce discharge, reduce fuel consumption, improve engine efficiency, improve a low-speed torque feature of the engines, and improve a low temperature cold start effect of the engines.